The storage ring proton EDM Experiment EOI Yannis Semertzidis BNL

1. Proton EDM in Storage Ring, PAC Presentation FNAL, 15 October 2012 The storage ring proton EDM Experiment EOIYannis Semertzidis BNL What is possible to achieve: 10-29ecm and with a lot of work 10-30ecm (stochastic cooling,…) Possible place: FNAL,…? How?

2. Sensitivity to Rule on Several New Models Electroweak Baryogenises GUT SUSY Gray: Neutron Red: Electron If found it could explain Baryogenesis (p, d, n (or 3He)) n current e current n target p, d target e target Upgrade? Statistics limited Much higher physics reach than LHC; complementary e-cm J.M.Pendlebury and E.A. Hinds, NIMA 440 (2000) 471

3. Nima Arkani-Hamed, Intensity Frontier Rockville, 2011

4. The proton EDM uses an ALL-ELECTRIC ring: spin is aligned with the momentum vector Momentum vector Spin vector At the magic momentum E the spin and momentum vectors precess at same rate in an E-field. Similar to muon g-2 method. E E E Yannis Semertzidis, BNL

5. The proton EDM proposal to DOE NP: November 2011 Weak vertical focusing to optimize SCT and BPM operation B: quadrupoles

6. Experiment Parameters • Proton magic momentum: 0.7 GeV/c (233 MeV kinetic) • E = 10.5 MV/m for 3 cm plate separation • R = 40 m;straight sections • Weak vertical focusing: vertical tune 0.30.1 • Stored particles: ~1010 per 103s, 104 injections

7. Proton Statistical Error (230MeV): p: 103sPolarization Lifetime (SpinCoherenceTime) A : 0.6 Left/right asymmetry observed by the polarimeter P : 0.8 Beam polarization Nc: 41010p/cycleTotal number of stored particles per cycle TTot: 107s Total running time per year f : 0.5% Useful event rate fraction (efficiency for EDM) ER : 10.5 MV/mRadial electric field strength (95% azim. cov.)

8. 40 m A proposed proton EDM ring location at BNL. It would be the largest diameter all-electric ring in the world. Booster AGS

9. What makes the pEDM experiment • Magic momentum (MM): high intensity charged beam in an all-electric storage ring • High analyzing power: A>50% at the MM • Weak vertical focusing in an all-electric ring: SCT allows for 103s beneficial storage; prospects for much longer SCT with mixing (cooling and heating) • The beam vertical position tells the average radial B-field; the main systematic error source • Geometrical-phase specs: 0.1mm

10. Clock-wise (CW) & Counter-Clock-wise Storage Any radial magnetic field sensed by the stored particles will also cause their vertical splitting. Equivalent to p-bar p colliders in Magnetic rings

11. What is critical The beam vertical position tells the average radial B-field; the main systematic error source D. Kawall First funding from US-Japan for testing at RHIC

12. 1. Beam Position Monitors (Need support to proceed) • Technology of choice: Low Tc SQUIDS, signal at ~104Hz (10% vertical tune modulation) • R&D sequence: (First funding from US-Japan) • Operate SQUIDS in a magnetically shielded area-reproduce current state of art • Operate in RHIC at an IP (evaluate noise in an accelerator environment)

13. 2. Polarimeter Development • Polarimeter tests with runs at COSY (Jülich/Germany) demonstrated < 1ppm level systematic errors: N. Brantjes et al., NIM A 664, 49, (2012) • Technologies under investigation: • Micro-Megas/Greece: high rate, pointing capabilities, part of R&D for ATLAS upgrade • MRPC/Italy: high energy resolution, high rate capability, part of ALICE development

14. 3. Spin Coherence Time: need >102 s • Not all particles have same deviation from magic momentum, or same horizontal and vertical divergence (all second order effects) • They cause a spread in the g-2 frequencies: • Present design parameters allow for 103s. Cooling/mixing during storage could prolong SCT (upgrade option?).

15. Spin Coherence Time • Several simulation efforts underway… • Runge-Kutta based:

16. Vert. tune = .1 Vertical oscillations Horizontal Oscill. dp/p Horizontal oscillations

17. What now? • BNL proposal: We expect to know NP DOE plans for the proton EDM by early 2013 • FNAL: DOE, HEP effort. Thetunnelis already here!

18. Fermi: need polarized proton source

19. And don’t forget proton EDM possibilities • See Y. Semertzidis talk this workshop • Frozen spin technique could produce proton EDM sensitivity just as good or better than electron or neutron EDMs • Looking at some Booster-based options • Directly inject 233 MeV protons into ring in current location of Accumulator • Important to have CW and CCW injection…tunnels already exist • Only uses a tiny fraction or beam power 19 Chris Polly, PXPS12, June 16, 2012

20. Technically driven pEDM timeline 15 18 12 13 14 16 17 19 20 21 • Two years R&D • One year final ring design • Two years ring/beam-line construction • Two years installation • One year “string test” DOE HEP project

21. Question: Demonstration Ring? • Maybe, e.g., similar size to muon g-2 ring. R&D work at JLAB Large grain Nb plates PRSTAB 15,083502, 2012

22. Question: Demonstration Ring? PRSTAB 15,083502, 2012 16 MV/m at 30 mm 69 MV/m at 3 mm

23. Demonstration-Ring Parameters • Ring circumference: 50 m • Bending radius:~7 m • Plate distance: 3 mm • Radial E-field: ~60 MV/m • High Voltage: ±90 kV

24. Demonstration-Ring Parameters • Proton Intensity (CW & CCW): ~107 / storage • Spin Coherence Time: ~105s • Projected (statistical) sensitivity: better than 10-26ecm • Running time: ~1 month

25. What do we learn? • All E-field ring issues: SCT, fringe field effects, ring admittance,… • BPM SQUID-magnetometers • B-field shielding, near DC, AC • Target for cost: ~10% of large ring

26. Summary • The collaboration is excited about the FNAL case (tunnel already there). • Polarized source plus some conventional construction required. • R&D support ($1.5M/y for two years) plus HEP strong endorsement needed • Demonstration ring with reasonable cost became a possibility (through R&D work)

27. Extra slides

28. PRSTAB 15,083502, 2012

29. E-field plate module: Similar to the (26) FNAL Tevatron ES-separators Beam position 0.4 m 3 m

30. Large Scale Electrodes, New: pEDM electrodes with HPWR

31. Is there an optimum m? m=0 m=0.01 Angle between spin and momentum [rad] m=0.04 R=40 m Time [s]

32. m = 0.006, tune:~0.08 Preliminary: Horizontal oscillations do not decohere the spins

33. SCT preliminary results for ~0.1 tune • More work needed • Vertical oscillations do not contribute to spin de-coherence (work by Yuri Orlov in agreement) • Horizontal betatron oscillations and dp/p<10-4 are good enough for 103s storage time • An “optimum” m= 0.006?

34. E-field model n=1+m, m=0: cylindrical plates. m=0.010.1 vertical tune; RF ON, 500KV

35. Software development • 4th order R.K. integrator Three different E-field dependences: 1/R Constant R0.2 Consistent with analytical estimations: Radial motion [m] vs. time [s]

36. Strong CP-problem and neutron EDM ~ ~1fm Order of magnitude estimation of the neutron EDM: M. Pospelov, A. Ritz, Ann. Phys. 318 (2005) 119. Yannis Semertzidis, BNL

37. EDMs of hadronic systems are mainly sensitive to Theta-QCD (part of the SM) CP-violating sources beyond the SM Alternative simple systems are needed to be able to differentiate the CP-violating source (e.g. neutron, proton, deuteron,…).

38. EDMs of different systems Theta_QCD: Measure all three: proton, deuteron and neutron EDMs to determine CPV source Super-Symmetry (SUSY) model predictions: It is possible to find the value of theta…

39. Muon g-2: Precision physics in a Storage Ring • Statistics limited… to improve sensitivity by a factor of 4 at Fermilab Yannis Semertzidis, BNL

40. Muon g-2: 4 Billion e+ with E>2GeV Sub-ppm accuracy, statistics limited Yannis Semertzidis, BNL

41. Breakthrough concept: Freezing the horizontal spin precession due to E-field Muon g-2 focusing is electric: The spin precession due to E-field is zero at “magic” momentum (3.1GeV/c for muons, 0.7 GeV/c for protons,…) The “magic” momentum concept was used in the muon g-2 experiments at CERN, BNL, and …next at FNAL.

42. Storage Ring EDM Collaboration • Aristotle University of Thessaloniki, Thessaloniki/Greece • Research Inst. for Nuclear Problems, Belarusian State University, Minsk/Belarus • Brookhaven National Laboratory, Upton, NY/USA • Budker Institute for Nuclear Physics, Novosibirsk/Russia • Royal Holloway, University of London, Egham, Surrey, UK • Cornell University, Ithaca, NY/USA • InstitutfürKernphysik and Jülich Centre for Hadron Physics Forschungszentrum Jülich, Jülich/Germany • Institute of Nuclear Physics Demokritos, Athens/Greece • University and INFN Ferrara, Ferrara/Italy • Laboratori Nazionali di Frascati dell'INFN, Frascati/Italy • Joint Institute for Nuclear Research, Dubna/Russia • Indiana University, Indiana/USA • Istanbul Technical University, Istanbul/Turkey • University of Massachusetts, Amherst, Massachusetts/USA • Michigan State University, East Lansing, Minnesota/USA • Dipartimento do Fisica, Universita’ “Tor Vergata” and Sezione INFN, Rome/Italy • University of Patras, Patras/Greece • CEA, Saclay, Paris/France • KEK, High Energy Accel. Res. Organization, Tsukuba, Ibaraki 305-0801, Japan • University of Virginia, Virginia/USA >20 Institutions >80 Collaborators http://www.bnl.gov/edm

43. Physics reach of magic pEDM (Marciano) The proton EDM at 10-29e∙cm has a reach of >300TeV or, if new physics exists at the LHC scale, <10-7-10-6 rad CP-violating phase; an unprecedented sensitivity level. The deuteron EDM sensitivity is similar. • Sensitivity to new contact interaction: 3000 TeV • Sensitivity to SUSY-type new Physics:

44. Extra slides Vertical Spin Component Time [s]

45. Total cost: exp + ring + beamline for two different ring locations @ BNL EDM ring+tunnel and beam line EDM ring

47. E-field strength The field emission withoutand withhigh pressure water rinsing (HPR) for 0.5cm plate separation. Recent developments in achieving high E-field strengths with HPR treatment (from Cornell ILC R&D)

48. Beam parameters • CW & CCW injections: Average emittance parameters: same to ~10% at injection. Fermi would need to get into polarized beams physics

49. Why does the world need a Storage Ring EDM experiment at the 10-29e-cm level ? The proton,deuteron and neutron combined can pin-down the CP-violating source should a non-zero EDM value is discovered. Critical: they can differentiate between a theta-QCD source and beyond the SM. The proton and deuteron provide a path to the next order of sensitivity. Yannis Semertzidis, BNL

50. High intensity charged particle beams can be stored for a long time Statistics: • High intensity (41010), highly polarized beams (>80%) • Keep spin along the momentum, radial E-field (10MV/m) acts on proton EDM • Long (~103s) spin coherence time (SCT) is shown • High efficiency (0.5%), with large analyzing power (50%) Systematics: • Magnetic field shielding + feedback to keep vertical spin <0.3mrad/storage • Store counter-rotating beams + BPMs to probe <Br> • Longitudinal impedance: <10KΩ • Forward/backward bunch polarizations (polarimeter) Software development: • Benchmarking at COSY with stored beams • At least two different approaches, speed, accuracy E E E E